Driver for the AKM AK9752 IR sensor device.
Library for the AK9752 Ultra-Small IR Sensor with I2C Interface. Includes integrated temperature sensor (0 - 50C) and 16-bit ADC.
AK9752.cpp
- Committer:
- masahikofukasawa
- Date:
- 2017-03-17
- Revision:
- 11:e4a64ed3ed58
- Parent:
- 10:1cb542a62421
- Child:
- 13:e02dfc48990a
File content as of revision 11:e4a64ed3ed58:
#include "AK9752.h" #include "AK9752_reg.h" /** * Combine low and high int8_t bytes of Temp/IR data and store in int16_t variable */ #define CONV16I(high,low) ((int16_t)(((high) << 8) | (low))) #define LEN_ONE_BYTE 1 /**<! Data length of 1 byte data. */ #define LEN_BUF_THRESHOLD 8 /**<! Data length of Threshold settings. From THIRH to THTMPL */ #define LEN_BUF_IR_DATA 7 /**<! Data length of IR sensor data: ST1,INTCAUSE,IR(16),TMP(16),ST2. */ #define VAL_SOFTWARE_RESET 0x01 /**<! Software reset value. */ #define ST1_STATUS_FLAG_DRDY 0x01 /**<! Data Ready*/ #define INT_STATUS_FLAG_DR 0x01 /**<! Data Read */ #define INT_STATUS_FLAG_TMPL 0x02 /**<! Temp low threshold reached */ #define INT_STATUS_FLAG_TMPH 0x04 /**<! Temp high threshold reached */ #define INT_STATUS_FLAG_IRL 0x08 /**<! IR low threshold reached */ #define INT_STATUS_FLAG_IRH 0x10 /**<! IR high threshold reached */ #define INT_STATUS_MASK 0x1F /**<! Mask highest 3 bits of status */ #define ST2_STATUS_FLAG_DOR 0x01 /**<! Data overrun (data read is required) */ AK9752::AK9752() { } void AK9752::init(I2C *conn, SlaveAddress addr) { slaveAddress = addr; connection = conn; } AK9752::Status AK9752::checkConnection() { // Gets the WIA register value - ID and ID2 char buf[2]; if ((AK9752::read(AK9752_REG_ADDR_WIA1, buf, 2)) != AK9752::SUCCESS) { return AK9752::ERROR; } // Manufacturer is AKM _and_ device is AK9752 _or_ device is AK9752-Prototype if ( (buf[0] == AK9752_REG_VALUE_WIA1) && (buf[1] == AK9752_REG_VALUE_WIA2) ) { return AK9752::SUCCESS; } else { return AK9752::ERROR; } } AK9752::Status AK9752::read(char registerAddress, char *buf, int length) { // Tell slave address of where to read data if (connection->write((slaveAddress << 1), ®isterAddress, LEN_ONE_BYTE) != 0) { // I2C write failed. return AK9752::ERROR_I2C_WRITE; } // Read register data (converts 7-bit address to 8-bit) if (connection->read((slaveAddress << 1), buf, length) != 0) { // I2C read failed. return AK9752::ERROR_I2C_READ; } return AK9752::SUCCESS; } AK9752::Status AK9752::write(char registerAddress, const char *buf, int length) { int bufLength = length + 1; // Increase size to account for address byte char data[bufLength]; // Creates data to be sent. data[0] = registerAddress; // Place register address in first byte for (int i=0; i < length; i++) { data[1+i] = buf[i]; // Load write data starting at second byte (i.e. data[1]) } // Initiate I2C write command if (connection->write((slaveAddress << 1), data, bufLength) != 0) { // I2C write failed. return AK9752::ERROR_I2C_WRITE; } return AK9752::SUCCESS; } AK9752::Status AK9752::getInterruptEnable(InterruptStatus *intStatus){ Status status; char buf = 0; if((status=read(AK9752_REG_ADDR_INTEN, &buf, LEN_ONE_BYTE)) != SUCCESS) { return status; // Read failed } // Set interrupt status flags individually intStatus->irh = ((buf & INT_STATUS_FLAG_IRH) > 0) ? true : false; intStatus->irl = ((buf & INT_STATUS_FLAG_IRL) > 0) ? true : false; intStatus->tmph = ((buf & INT_STATUS_FLAG_TMPH) > 0) ? true : false; intStatus->tmpl = ((buf & INT_STATUS_FLAG_TMPL) > 0) ? true : false; intStatus->dr = ((buf & INT_STATUS_FLAG_DR) > 0) ? true : false; return SUCCESS; // Read succeeded } AK9752::Status AK9752::setInterruptEnable(const InterruptStatus *intStatus) { char buf = 0; // If interrupt bit is 1, set corresponding buf bit to 1, otherwise set to 0 buf += intStatus->irh ? INT_STATUS_FLAG_IRH : 0; buf += intStatus->irl ? INT_STATUS_FLAG_IRL : 0; buf += intStatus->tmph ? INT_STATUS_FLAG_TMPH : 0; buf += intStatus->tmpl ? INT_STATUS_FLAG_TMPL : 0; buf += intStatus->dr ? INT_STATUS_FLAG_DR : 0; // Perform interrupt status write operation Status status; if ((status=write(AK9752_REG_ADDR_INTEN, &buf, LEN_ONE_BYTE)) != SUCCESS) { return status; } // Read back the interrupt status char readback = 0; if ((status=read(AK9752_REG_ADDR_INTEN, &readback, LEN_ONE_BYTE)) != SUCCESS) { return status; // Read back operation failed } if ((readback & INT_STATUS_MASK) != buf) { return ERROR; // Read back succeeded, but values incorrect } return SUCCESS; } AK9752::Status AK9752::setThreshold(const Threshold *th) { Status status; char buf[LEN_BUF_THRESHOLD]; // Mask off irrelevant byte, cast 8-bit values to 16-bit // buf[0] = (char)(((uint16_t)th->thirh & 0x00FF)); // THIRHL Register buf[1] = (char)(((uint16_t)th->thirh & 0xFF00) >> 8); // THIRHH Register buf[2] = (char)(((uint16_t)th->thirl & 0x00FF)); // THIRLL Register buf[3] = (char)(((uint16_t)th->thirl & 0xFF00) >> 8); // THIRLH Register buf[4] = (char)(((uint16_t)th->thtmph & 0x00FF)); // THTMPHL Register buf[5] = (char)(((uint16_t)th->thtmph & 0xFF00) >> 8); // THTMPHH Register buf[6] = (char)(((uint16_t)th->thtmpl & 0x00FF)); // THTMPLL Register buf[7] = (char)(((uint16_t)th->thtmpl & 0xFF00) >> 8); // THTMPLH Register // Perform threshold register write operaton if ((status=write(AK9752_REG_ADDR_THIRHL, buf, LEN_BUF_THRESHOLD)) != SUCCESS) { return status; // Write operation failed } return SUCCESS; // Write operation succeeded } AK9752::Status AK9752::getThreshold(Threshold *th) { Status status; char buf[LEN_BUF_THRESHOLD]; // Perform threshold register read operation if ((status=read(AK9752_REG_ADDR_THIRHL, buf, LEN_BUF_THRESHOLD)) != SUCCESS) { return status; // Read operation failed } // Combine low and high bytes of data th->thirh = CONV16I(buf[1], buf[0]); th->thirl = CONV16I(buf[3], buf[2]); th->thtmph = CONV16I(buf[5], buf[4]); th->thtmpl = CONV16I(buf[7], buf[6]); return SUCCESS; // Read operation succeeded } AK9752::Status AK9752::getOperationMode(OperationMode *mode, FcTmp *fc_tmp, FcIr *fc_ir){ Status status; char buf[2]; if ((status=read(AK9752_REG_ADDR_CNTL1, buf, 2)) != SUCCESS) { return status; // Read operation failed } *fc_tmp = AK9752::FcTmp((buf[0] & 0x1C)>>2); // Read CNTL1[2]-CNTL1[4] *fc_ir = AK9752::FcIr(buf[0] & 0x03); // Read CNTL1[0]-CNTL1[1] *mode = AK9752::OperationMode(buf[1] & 0x03); // Read CNTL2[0]-CNTL2[1] return SUCCESS; // Read operation succeeded } AK9752::Status AK9752::setOperationMode(OperationMode mode, FcTmp fc_tmp, FcIr fc_ir){ Status status; char buf[2]; buf[0] = (fc_tmp<<2 | fc_ir&0x03); // Combine FCTMP & FCIR in 1 byte buf[1] = mode; // Write 2 bytes starting from CNTL1 -> write CNTL1 and CNTL2 if ((status=write(AK9752_REG_ADDR_CNTL1, buf, 2)) != SUCCESS) { return status; // Write operation failed } return SUCCESS; // Write operation succeeded } AK9752::Status AK9752::reset() { Status status; char val = VAL_SOFTWARE_RESET; // char instance required for write() if ((status=write(AK9752_REG_ADDR_CNTL3, &val, LEN_ONE_BYTE)) != SUCCESS) { return status; // Write operation failed } return SUCCESS; // Write operation succeeded } AK9752::Status AK9752::getSensorData(SensorData *data) { char buf[LEN_BUF_IR_DATA]; // Read 7 bytes starting at ST1: reads ST1, INTCAUSE, data and ST2 at once if ((read(AK9752_REG_ADDR_ST1, buf, LEN_BUF_IR_DATA)) != SUCCESS) { return ERROR; // Read operation failed } // Check Data ReaDY if( (buf[0] & ST1_STATUS_FLAG_DRDY) == 0 ){ // DRDY=0, data not ready return ERROR; } // Read IR threshold, temp threshold and data ready flags data->intStatus.irh = ((buf[1] & INT_STATUS_FLAG_IRH) > 0) ? true : false; data->intStatus.irl = ((buf[1] & INT_STATUS_FLAG_IRL) > 0) ? true : false; data->intStatus.tmph = ((buf[1] & INT_STATUS_FLAG_TMPH) > 0) ? true : false; data->intStatus.tmpl = ((buf[1] & INT_STATUS_FLAG_TMPL) > 0) ? true : false; data->intStatus.dr = ((buf[1] & INT_STATUS_FLAG_DR) > 0) ? true : false; // Extract IR sensor data data->ir = (int16_t)((buf[3] << 8) | buf[2]); // Combine IRL & IRH // Extract Temperature sensor data data->temperature = (int16_t)((buf[5] << 8) | buf[4]); // Combine TMPL & TMPH // Extract Data Overrun status data->dor = ((buf[1] & ST2_STATUS_FLAG_DOR) > 0) ? true : false; return SUCCESS; } AK9752::Status AK9752::isDataReady() { AK9752::Status status = AK9752::ERROR; char stValue[1]; if ((status=AK9752::read(AK9752_REG_ADDR_ST1, stValue, 1)) != AK9752::SUCCESS) { // I2C read failed. return status; } // Sets a return status corresponds to the obtained value. if ((stValue[0] & AK9752_ST1_MASK_DRDY) > 0) { status = AK9752::DATA_READY; } else { status = AK9752::NOT_DATA_READY; } return status; }